Papers
Screening for Down's syndrome: effects, safety, and cost
effectiveness of first and second trimester strategiesCommentary: Results may not be widely applicableAuthors' response
Screening for Down's syndrome: effects, safety, and cost
effectiveness of first and second trimester strategies
R E Gilbert a Systematic Reviews Training Unit,
Department of Paediatric Epidemiology and Biostatistics, Institute of
Child Health, London WC1N 1EH, b Department of Paediatric Epidemiology and
Biostatistics, Institute of Child Health, c Centre for Health
Economics, University of York, Heslington, York YO1 5DD, d Health Services
Research Unit, Department of Public Health and Policy, London School of
Hygiene and Tropical Medicine, London WC1E 7HT Correspondence to: R E Gilbert
r.gilbert{at}ich.ucl.ac.uk
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Abstract |
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 Abstract
Introduction
Methods
Results
Discussion
References
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Objective:
To compare the effects, safety, and cost
effectiveness of antenatal screening strategies for Down's syndrome.
Design:
Analysis of incremental cost effectiveness.
Setting:
United Kingdom.
Main outcome measures:
Number of liveborn babies with
Down's syndrome, miscarriages due to chorionic villus sampling or
amniocentesis, healthcare costs of screening programme, and additional
costs and additional miscarriages per additional affected live birth prevented by adopting a more effective strategy.
Results:
Compared with no screening, the additional cost per additional liveborn baby with Down's syndrome prevented was
£22 000 for measurement of nuchal translucency. The cost of the
integrated test was £51 000 compared with measurement of nuchal translucency. All other strategies were more costly and less effective, or cost more per additional affected baby prevented. Depending on the
cost of the screening test, the first trimester combined test and the
quadruple test would also be cost effective options.
Conclusions:
The choice of screening strategy should
be between the integrated test, first trimester combined test,
quadruple test, or nuchal translucency measurement depending on how
much service providers are willing to pay, the total budget available, and values on safety. Screening based on maternal age, the second trimester double test, and the first trimester serum test was less
effective, less safe, and more costly than these four options.
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What is already known on this topic
What this study adds
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Introduction |
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Discussion
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The provision of screening services in the NHS lags far behind advances in performance of screening tests over the past decade.1 In 1998, 57% of antenatal care providers offered the second trimester double test for Down's syndrome and 8% offered screening based only on maternal age.2 Few NHS providers offered the more effective nuchal translucency measurement (7%) or quadruple test (3%). The integrated test, which is the most effective screening test and involves testing in the first and second trimesters,3 is available only privately.
The main considerations for providers of screening for Down's syndrome
should be minimising the risk of babies with Down's syndrome being
missed by the test, reducing miscarriage due to amniocentesis or
chorionic villus sampling, and costs. We therefore compared the
effects, safety, and cost effectiveness of nine strategies currently
available for screening for Down's syndrome in the United Kingdom.
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Methods |
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Methods
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Discussion
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Decision model
We compared no screening with nine screening strategies offered in
the first or second trimesters (table 1). Prenatal diagnosis included
abdominal chorionic villus sampling before 15 weeks' gestation or
amniocentesis thereafter if screening indicated a greater than 1 in 300 risk of Down's syndrome. We determined the number of liveborn children
with and without Down's syndrome, pregnancy losses (including
terminations, spontaneous losses, and miscarriages due to chorionic
villus sampling or amniocentesis), and the healthcare cost of the
screening programme in 10 000 women with the age distribution of women
delivering in England and Wales in 1995.
Model estimates
Estimates used in the model are based on a systematic
review,1 other published sources, and discussions with a
reference group of UK service providers and users (see acknowledgements). We assumed that 100% of women attend antenatal clinic between 10 and 14 completed weeks of gestation (median 12 weeks
gestation) and are offered tests in the first trimester or between 15 and 19 weeks (median 15 weeks) for tests in the second trimester. Table
1 gives the time required for counselling and for processing of
screening and diagnostic tests and the proportion of women accepting
procedures.
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for example, substitution of free
human chorionic gonadotrophin for total human chorionic gonadotrophin or inhibin A for unconjugated oestriol, would not substantially affect test performance. We assumed that all women would
have an ultrasound dating scan and that, for second trimester serum
tests, maternal weight would be taken into account.
We estimated the risk of giving birth to a Down's syndrome baby for
each woman, based on the screening test results and maternal age.
Firstly, we calculated the distribution of likelihood ratios for the
screening test separately for pregnancies affected and unaffected by
Down's syndrome using Monte Carlo simulation12 and
assumed independence between the nuchal translucency measurement, first
trimester serum test (PAPP-A), and quadruple test. We then calculated
the distributions of risk of an affected pregnancy for each year of
maternal age by multiplying likelihood ratios by the age specific risk
of an affected live birth. Finally, we calculated a single, age
specific distribution of risk after screening by taking account of the
proportion of pregnant women at each maternal age and the age specific
risk of Down's syndrome.
Cost
The costs of screening tests included laboratory expenses
(consumables and staff), informing the women of the results (by
telephone if positive, by post if negative), service costs (including
processing results and monitoring the service), overheads, and (for
nuchal translucency measurement) training (table 1). The costs of
chorionic villus sampling and amniocentesis included counselling before
the procedure, equipment and staff to do the procedure, laboratory
expenses (consumables and staff, non-reagent and labour costs), and
overheads. For all these costs, we assumed an existing infrastructure
for antenatal screening and diagnosis of Down's syndrome. We also
estimated costs of events arising from screening (table 2) All costs
were adjusted to June 1998 prices (for full details see
www.ich.ucl.ac.uk/srtu).
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Sensitivity analyses
The sensitivity analyses examined the effect of a 50% increase
and decrease in the costs of chorionic villus sampling, amniocentesis,
the screening test, and nuchal translucency measurement. We also tested
the effect of varying the cut-off point for a positive result.
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Results |
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Methods
Results
Discussion
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Effects and costs
Table 3 and the figure show the effects and costs of no
screening and of the nine screening strategies. Measurement of nuchal
translucency would result in 7.6 fewer births of babies with Down's
syndrome compared with no antenatal screening, at a total cost of
£171 000 per 10 000 pregnant women. The incremental cost
effectiveness ratio for nuchal translucency compared with no screening
is £22 000 (171 000/7.6) per prevented birth of a baby with Down's
syndrome. The integrated test results in 2.0 fewer births of babies
with Down's syndrome than the nuchal translucency measurement at a
total cost of £276 000. The incremental cost effectiveness ratio of
the integrated test compared with nuchal translucency is £52 000
(276 000
171 000)/2.0) per affected baby prevented.
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Effects and safety
The integrated test is the most effective and safest strategy. All
other strategies result in more liveborn babies with Down's syndrome
and more miscarriages of unaffected pregnancies due to amniocentesis or
chorionic villus sampling. Compared with no screening, the integrated
test results in 0.14 miscarriages due to chorionic villus sampling or
amniocentesis per birth of a Down's syndrome baby prevented. The next
safest strategies, compared with no screening, are the first trimester combined test (0.22 miscarriages), nuchal translucency measurement (0.34), and the quadruple test (0.42).
Sensitivity analyses
A 50% increase or decrease in the unit costs of chorionic
villus sampling and amniocentesis would hardly alter the cost
effectiveness. If the cost of amniocentesis fell by 50%, the quadruple
test would enter the efficiency frontier (cost effectiveness ratio
compared with nuchal translucency £39 000 and for the integrated test
compared with the quadruple test £51 000).
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Discussion |
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Introduction
Methods
Results
Discussion
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The nuchal translucency measurement, quadruple test, first trimester combined, and integrated tests represent the best options in terms of effectiveness, cost effectiveness, and safety. All other strategies would be less effective, cost more per additional birth of an affected baby prevented, and be less safe. This finding was robust in the sensitivity analyses.
The choice between the four options depends on how much service providers are willing to pay to prevent one affected liveborn baby, on the total budget available for antenatal screening, and on how much service providers value safety. We would expect service providers to be willing to spend at least £30 000 to £40 000 per additional affected baby prevented, as this reflects the incremental costs paid by most service providers that offer screening to all women.14
Implications for practice
These findings contrast with current practice in the United
Kingdom, where the second trimester double test is most commonly
offered.2 Moving from the double test to the first
trimester combined test or quadruple test would not cost any more and
would result in 1.5 (for the first trimester combined) or 1.2 (for the
quadruple test) fewer affected liveborn babies for every 10 000
pregnancies (table 2). Alternatively, the nuchal translucency
measurement would be more effective than the double test (0.3 fewer
affected babies) at a total cost saving of £70 000. Finally, moving
from the double test to the integrated test would result in 2.3 fewer
affected babies and cost £13 000 per additional affected baby prevented.
Implementation issues
Our results are susceptible to variation in performance of
screening tests. The performance of serum markers in pregnancies
affected by Down's syndrome is highly consistent across different
studies,1 whereas performance of nuchal translucency measurement varies widely.
17 18
Such variation may be
explained by verification bias, chance, referral patterns, variation in test reliability,19 and the use of repeated measurements.
We used performance characteristics for nuchal translucency measurement derived from routine screening of 95 000 pregnancies, which were then
adjusted for verification bias.4 However, we do not know how much test performance was optimised by repeated measurements or
referral for a second opinion. In addition, the performance of the
integrated test, which was derived by combining test characteristics for serum tests and the nuchal translucency measurement from different datasets, needs to be evaluated in a study of pregnant women.
3mm and would diminish the detection rate of nuchal
translucency measurement.
20 21
In our analysis, a
relative risk of 2.8 would result in 1.3 more liveborn babies with
Down's syndrome per 10 000 pregnancies after measuring nuchal translucency, but the strategy would still be cost effective.
The choice of screening strategy may be affected by several factors
that were beyond the scope of our analysis. Firstly, we did not adopt a
societal perspective,13 which would seek to maximise
health gain for a given cost. Such analyses are problematic in terms of
measures of effectfor example, should the outcome measure be
prevented liveborn baby with Down's syndrome or quality adjusted life
years.22 There are also difficult decisions about which
costs to include. Some previous cost effectiveness analyses included
direct and indirect lifetime incremental costs per liveborn baby with
Down's syndrome (including education, health, and lost productivity).
These ranged from £85 000 in 199023 to £340 000 in
1996.24 The studies avoided including other indirect costs attributable to fetal losses by assuming a replacement pregnancy.
If the lowest estimate (£85 000) for the incremental lifetime
costs associated with a Down's syndrome child is included in our
analysis the net saving compared with no screening would be largest for
the integrated test. The net saving would be £548 000 (costs avoided
(9.7 Down's syndrome babies prevented × £85 000)screening
programme costs (£276 000)).
Factors that could affect results
Three factors that we did not consider may affect our
results. Firstly, capital costs for additional laboratory or clinical
capacity may be incurred for use of the enzyme linked immunosorbent
assay (ELISA) test for inhibin A (the fourth serum marker in the
quadruple test), implementation of routine nuchal translucency
measurement, or the creation of additional facilities for chorionic
villus sampling. Secondly, uptake of all screening tests and
termination may not be the same for all strategies and may be lower for
the integrated test, which requires two visits. Decreased uptake of
termination in later pregnancy is likely and would mean that our
analysis overestimates the effectiveness of the integrated and
quadruple tests. Thirdly, service providers need to provide for women
who attend antenatal booking clinic after the first trimester (up to
35% based on results from 21 000 women in six inner London maternity
units25). Alternative strategies for late attenders
include no screening, the quadruple test, or strategies to encourage
earlier attendance at antenatal booking clinicfor example, by
speeding up referrals from primary care.
Conclusions
The choice of screening strategy should be between the
integrated test, first trimester combined test, quadruple test, or
nuchal translucency measurement. Screening based on maternal age, the
second trimester double test, and the first trimester serum test would
be less effective, less safe, and more costly than these four options.
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Acknowledgments |
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John Kingdom and Susan Bewley provided advice on the development of the project and commented on drafts of the report. Maureen Dalziel chaired the reference group and commented on the study design. Roxanne Chamberlain, Jean Chapple, Nick Fisk, Mike Gill, David Highton, M L Ko, Mike Lobb, Lucy Moore, Tracey Reeves, and Tracy Stein were members of the reference group and commented on the study design and results. Susan Bewley, Elizabeth Dormandy, Ross Hastings, Wayne Huttly, Linda Mulhair, Kypros Nicolaides, and Pran Pandya provided information on screening practices. The report may not reflect the views of the funding body.
Contributors: REG, AEA, SL, MS, and JHPvdM contributed to the study design. CA reviewed the literature. RG did the computer programming, which was supervised by AEA. MS advised on the economic analysis. JHPvdM devised the analytical strategy for the screening tests. All authors contributed to writing the manuscript. REG wrote the final version, and acts as guarantor for the study.
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Footnotes |
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Funding: The project was commissioned by Maureen Dalziel, Sally Davies, and Ron Kerr from the London regional office of the NHS Executive.
Competing interests: None declared.
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References |
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Abstract
Introduction
Methods
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Discussion
References
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| 1. | Wald NJ, Kennard A, Hackshaw A, McGuire A. Antenatal screening for Down's syndrome. J Med Screen 1997; 4: 181-246[Medline]. |
| 2. | Wald NJ, Huttly WJ, Hennessy CF. Down's syndrome screening in the UK in 1998. Lancet 1999; 354: 1264[Medline]. |
| 3. |
Wald NJ, Watt HC, Hackshaw AK.
Integrated screening for Down's syndrome based on tests performed during the first and second trimesters.
N Engl J Med
1999;
341:
461-467 |
| 4. | Nicolaides KH, Snijders RJ, Cuckle HS. Correct estimation of parameters for ultrasound nuchal translucency screening. Prenat Diagn 1998; 18: 519-523[CrossRef][Medline]. |
| 5. | Wald NJ, Hackshaw AK. Combining ultrasound and biochemistry in first-trimester screening for Down's syndrome. Prenat Diagn 1997; 17: 821-829[CrossRef][Medline]. |
| 6. | Hecht CA, Hook EB. The imprecision in rates of Down syndrome by 1-year maternal age intervals: a critical analysis of rates used in biochemical screening. Prenat Diagn 1994; 14: 729-738[Medline]. |
| 7. | Wald NJ, Cuckle HS, Densem JW, Nanchahal K, Royston P, Chard T, et al. Maternal serum screening for Down's syndrome in early pregnancy. BMJ 1988; 297: 883-887. |
| 8. | Wald NJ, Cuckle HS, Densem JW, Kennard A, Smith D. Maternal serum screening for Down's syndrome: the effect of routine ultrasound scan determination of gestational age and adjustment for maternal weight. Br J Obstet Gynaecol 1992; 99: 144-149[Medline]. |
| 9. | Wald NJ, Densem JW, George L, Muttukrishna S, Knight PG. Prenatal screening for Down's syndrome using inhibin-A as a serum marker. Prenat Diagn 1996; 16: 143-153[CrossRef][Medline]. |
| 10. | Macintosh MC, Wald NJ, Chard T, Hansen J, Mikkelsen M, Therkelsen AJ, et al. Selective miscarriage of Down's syndrome fetuses in women aged 35 years and older. Br J Obstet Gynaecol 1995; 102: 798-801[Medline]. |
| 11. | Snijders RJ, Noble P, Sebire N, Souka A, Nicolaides KH. UK multicentre project on assessment of risk of trisomy 21 by maternal age and fetal nuchal-translucency thickness at 10-14 weeks of gestation. Fetal Medicine Foundation First Trimester Screening Group. Lancet 1998; 352: 343-346[CrossRef][Medline]. |
| 12. | Van der Meulen JHP, Mol BW, Pajkrt E, van Lith JM, Voorn W. Use of the disutility ratio in prenatal screening for Down's syndrome. Br J Obstet Gynaecol 1999; 106: 108-115[Medline]. |
| 13. | Siegel JE, Weinstein MC, Torrance GW. Reporting cost-effectiveness studies and results. In: Gold MR, Siegel JE, Russell LB, Weinstein MC, eds. Cost effectiveness in health and medicine. New York: Oxford University Press, 1996:276-312. |
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Torgerson DJ, Spencer A.
Marginal costs and benefits.
BMJ
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35-36 |
| 15. | Heckerling PS, Verp MS, Hadro TA. Preferences of pregnant women for amniocentesis or chorionic villus sampling for prenatal testing: comparison of patients' choices and those of a decision-analytic model. J Clin Epidemiol 1994; 47: 1215-1228[CrossRef][Medline]. |
| 16. | Kuppermann M, Feeny D, Gates E, Posner SF, Blumberg B, Washington AE. Preferences for women facing a prenatal diagnostic choice: long-term outcomes matter most. Prenat Diagn 1999; 19: 711-716[CrossRef][Medline]. |
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Palomaki GE, Knight GJ, McCarthy JE, Haddow JE, Donhowe JM.
TI-Screening of maternal serum for fetal Down's syndrome in the first trimester.
N Engl J Med
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| 18. | Mol BW, Lijmer JG, van der Meulen JHP, Pajkrt E, Bilardo CM, Bossuy PM. Effect of study design on the association between nuchal translucency measurement and Down syndrome. Obstet Gynecol 1999; 94: 864-869[CrossRef][Medline]. |
| 19. | Pajkrt E, Mol BW, Boer K, Drogtrop AP, Bossuyt PM, Bilardo CM. Intra- and interoperator repeatability of the nuchal translucency measurement. Ultrasound Obstet Gynecol 2000; 15: 297-301[CrossRef][Medline]. |
| 20. | Hyett J, Moscoso G, Papapanagiotou G, Perdu M, Nicolaides KH. Abnormalities of the heart and great arteries in chromosomally normal fetuses with increased nuchal translucency thickness at 11-13 weeks of gestation. Ultrasound Obstet Gynecol 1996; 7: 245-250[CrossRef][Medline]. |
| 21. | Bewley S, Roberts LJ, Mackinson AM, Rodeck C. First trimester fetal nuchal translucency: problems with screening the general population.2. Br J Obstet Gynaecol 1995; 102: 386-388[Medline]. |
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Ganiats TG.
Justifying prenatal screening and genetic amniocentesis programs by cost-effectiveness analyses: a re-evaluation.
Med Decis Making
1996;
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Shackley P, McGuire A, Boyd PA, Dennis J, Fitchett M, Kay J, et al.
An economic appraisal of alternative prenatal screening programmes for Down's syndrome.
J Public Health Med
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175-184 |
| 24. | Beazoglou T, Heffley D, Kyriopoulos J, Vintzileos A, Benn P. Economic evaluation of prenatal screening for Down syndrome in the USA. Prenat Diagn 1998; 18: 1241-1252[CrossRef][Medline]. |
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Gibb DM, MacDonagh SE, Gupta R, Tookey PA, Peckham CS, Ades AE.
Factors affecting uptake of antenatal HIV testing in London: results of a multicentre study.
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(Accepted 21 May 2001)
Commentary: Results may not be widely applicable
Euan M Wallace Centre for
Women's Health Research, Department of Obstetrics and Gynaecology,
Monash University, Monash Medical Centre, Clayton, Victoria 3168, Australia
Correspondence to: E M Wallace
euan.wallace{at}med.monash.edu.au
The average age at which women in Western countries
choose to have children continues to increase. Although this trend has several important implications for the outcome of pregnancy, one of the
most obvious effects is an increase in the incidence of Down's
syndrome.1 Prenatal screening for Down's syndrome has become an established part of antenatal care in many centres, resulting
in a reduction in the number of babies born with Down's syndrome in
the populations screened.1
Several serum markers of Down's syndrome have been described, and
different screening programmes use different combinations of markers,
making it difficult to compare their results.2 The recent
introduction of first trimester serum and ultrasound screening has
further complicated such comparisons. Therefore, it is often unclear
which screening strategy is the most effective, the most cost
effective, or the most appropriate for a given setting. Gilbert and her
colleagues summarise various approaches to screening and describe the
most cost effective strategies. Such information will be invaluable to
all those providing antenatal care.
Limitations
Some authorities are likely to disagree with the conclusions
reached by Gilbert et al. There is evidence that simple two marker
protocols (such as 
fetoprotein and free ß human chorionic
gonadotrophin) can achieve higher detection rates than those estimated
by Gilbert et al for more complex combinations, even after correction
for the high rate of spontaneous loss of pregnancies affected by
Down's syndrome.
2 3
How can this be?
Women's views
What is not covered by these analyses, although the authors
mention it, is patient preference. We have little information about
what women prefer in screening, but there is some evidence that they
want testing as early in pregnancy as possible, even if a later test
performs slightly better.6 Such information is surely
fundamental to the development of future screening programmes. It would
be unfortunate if the technical advances in screening were assessed and
compared without considering women's wishes. Similarly, it is
unacceptable that access to screening for Down's syndrome varies
across the United Kingdom. Contributions such as that by Gilbert et al
will inform relevant authorities, such as the UK National Screening
Committee, and help ensure that appropriate and high quality screening
is available to all women who want it.
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Footnotes |
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Competing interests: EMW holds the patent for use of inhibin A as a marker of Down's syndrome.
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References |
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Top
References
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| 1. | Cheffins T, Chan A, Haan EA, Ranieri E, Ryall RG, Keane RJ, et al. The impact of maternal serum screening on the birth prevalence of Down's syndrome and the use of amniocentesis and chorionic villus sampling in South Australia. Br J Obstet Gynaecol 2000; 107: 1453-1459. |
| 2. | Wald NJ, Kennard A, Hackshaw A, McGuire A. Antenatal screening for Down's syndrome. J Med Screen 1997; 4: 181-246. |
| 3. | Spencer K. Second trimester prenatal screening for Down's syndrome using alpha-fetoprotein and free beta hCG: a seven year review. Br J Obstet Gynaecol 1999; 106: 1287-1293[Medline]. |
| 4. | Berry E, Aitken DA, Crossley JA, Macri JN, Connor JM. Screening for Down's syndrome: changes in marker levels and detection rates between first and second trimesters. Br J Obstet Gynaecol 1997; 104: 811-817[Medline]. |
| 5. | Vintzileos AM, Ananth CV, Smulian JC, Day-Salvatore DL, Beazoglou T, Knuppel RA. Cost-benefit analysis of prenatal diagnosis for Down syndrome using the British or the American approach. Obstet Gynecol 2000; 95: 577-583[CrossRef][Medline]. |
| 6. | Mulvey S, Wallace EM. Women's knowledge of and attitudes to first and second trimester screening for Down's syndrome. Br J Obstet Gynaecol 2000; 107: 1302-1305. |
Authors' response
Wallace and Mulvey criticise our study for relying on a
single archived serum bank. Instead, they advocate comparing detection rates from "prospective studies," by which they mean routinely collected hospital data. We disagree. It is well known that data from
routine practice may overestimate the performance of screen tests
because positive results lead to interventions whereas affected pregnancies with negative results may not be counted (termed
verification bias).1 Such bias depends on the gestational
age at testing and can be allowed for only indirectly. Differences in
detection rates (assuming a constant false positive rate) may also
relate to uptake of interventions and referral patterns. Finally, we required the test performance characteristics rather than the detection
rate in order to standardise for age and cut-off point for positivity.
The study based on an archived serum bank avoided biased detection of
affected fetuses (all were karyotyped), took account of ultrasound
pregnancy dating, and reported performance characteristics for all the
serum tests.
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References |
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| 1. | Mol BW, Lijmer JG, van der Meulen J, Pajkrt E, Bilardo CM, Bossuyt PM. Effect of study design on the association between nuchal translucency measurement and Down syndrome. Gynecol 1999; 94: 864-869. |
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